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金属学报 2014

间隙原子C作用下TiAl合金中析出相的形成及演变规律*

DOI: 10.3724/SP.J.1037.2013.00746, PP. 832-838

周欢,张铁邦,吴泽恩,胡锐,寇宏超,李金山

Keywords: 间隙原子,高Nb-TiAl合金,碳化物,演化,位向关系

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Abstract:

采用XRD,SEM及TEM分析研究间隙原子C作用下Ti-46Al-8Nb-xC(x=0,0.7,1.4,2.5,原子分数,%)合金中析出相的形成规律、析出相与基体相的位向关系及其在热处理过程中的演变规律.结果表明,在C含量为1.4%和2.5%的合金中有长条状Ti2AlC析出,该析出相在铸锭制备的过程中形成,在时效热处理中尺寸、数量和分布均无明显变化,表现出较好的稳定性.不同C含量合金经固溶处理和时效后析出细小针状的Ti3AlC,该析出相从g相中析出,并与γ相存在位向关系,.延长时效时间,Ti3AlC尺寸略有增大,数量变化不明显;升高时效温度,Ti3AlC的尺寸和数量均有显著增加.

References

[1]	Loria E A. Intermetallics, 2000; 8: 1339
[2]	Kothari K, Radhakrishnan R, Wereley N M. Prog Aerosp Sci, 2012; 55: 1
[3]	Noda T. Intermetallics, 1998; 6: 709
[4]	Dimiduk D M. Mater Sci Eng, 1999; A263: 281
[5]	Yu H C, Dong C L, Jiao Z H, Kong F T, Chen Y Y, Su Y J. Acta Metall Sin, 2013; 49: 1311 (于慧臣, 董成利, 焦泽辉, 孔凡涛, 陈玉勇, 苏勇君. 金属学报, 2013; 49: 1311)
[6]	Appel F, Oehring M, Wagner R. Intermetallics, 2000; 8: 1283
[7]	Gerling R, Schimansky F P, Stark A, Bartels A, Kestler H, Cha L, Scheu C, Clemens H. Intermetallics, 2008; 16: 689
[8]	Perdrix F, Trichet M F, Bonnentien J L, Cornet M, Bigot J. Intermetallics, 2001; 9: 807
[9]	Hecht U, Witusiewicz V, Drevermann A, Zollinger J. Intermetallics, 2008; 16: 969
[10]	Clemens H, Mayer S. Adv Eng Mater, 2013; 15: 191
[11]	Wu Z E, Hu R, Zhang T B, Zhou H, Kou H C, Li J S. Acta Metall Sin, 2013; 49: 1381 (吴泽恩, 胡锐, 张铁邦, 周欢, 寇宏超, 李金山. 金属学报, 2013; 49: 1381)
[12]	Dong L M, Cui Y Y, Yang R. Acta Metall Sin, 2002; 38: 643(董利民, 崔玉友, 杨锐. 金属学报, 2002; 38: 643)
[13]	Scheu C, Stergar E, Schober M, Cha L, Clemens H, Bartels A, Schimansky F P, Cerezo A. Acta Mater, 2009; 57: 1504
[14]	Christoph U, Appel F, Wagner R. Mater Sci Eng, 1997; A239: 39
[15]	Chen S, Beaven P A, Wagner R. Scr Metall Mater, 1992; 26: 1205
[16]	Tian W H, Nemoto M. Intermetallics, 1997; 5: 237
[17]	Appel F, Paul J D H, Oehring M. Gamma Titanium Aluminide Alloys: Science and Technology. Weinheim: Wiley-VCH, 2011: 282
[18]	Gabrisch H, Stark A, Schimansky F P, Wang L, Schell N, Lorenz U, Pyczak F. Intermetallics, 2013; 33: 44
[19]	Li S J, Wang Y L, Lin J P, Lin Z, Chen G L. Rare Met Mater Eng, 2004; 33: 144(李书江, 王艳丽, 林均品, 林志, 陈国良. 稀有金属材料与工程, 2004; 33: 144)
[20]	Pietzka M A, Schuster J C. J Phase Equilib, 1994; 15: 392
[21]	Cam G, Flower H M, West D R F. MaterSci Technol, 1991; 7: 505
[22]	Kurz W, Fisher D J, translated by Li J G, Hu Q D. Fundamentals of Solidification. 4th Ed., Beijing: Higher Education Press, 2010: 18 (Kurz W, Fisher D J 著, 李建国, 胡侨丹译. 凝固原理. 第四版, 北京: 高等教育出版社, 2010: 18)
[23]	Wei Z, Wang H, Jin Y, Zhang H, Zeng S. J Mater Sci, 2002; 37: 1809
[24]	Chen G L, Xu X J, Teng Z K, Wang Y L, Lin J P. Intermetallics, 2007; 15: 625
[25]	Chen Z, Su X, Xiang Z, Nie Z. J Mater Sci Technol, 2012; 28: 453
[26]	Xia Q F, Wang J N, Yang J, Wang Y. Intermetallics, 2001; 9: 361
[27]	Wang P, Viswanathan G B, Vasudevan V K. Metall Trans, 1992; 23A: 690
[28]	Menand A, Huguet A, Nerac-Partaix A. Acta Mater, 1996; 44: 4729
[29]	Kanchana V. EPL-Europhys Lett, 2009; 87: 26006
[30]	Tian W H, Sano T, Nemoto M. Philos Mag, 1993; 68A: 965
[31]	Xu Z, Zhao L C. Metal-Solid Phase Transition Theory. Beijing: Science Press, 2004: 7 (徐洲, 赵连城. 金属固态相变原理. 北京: 科学出版社, 2004: 7)

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